Screw element for same-sense rotating multi-screw extruders

ABSTRACT

The invention relates to a screw element with an outer radius R a  and a core radius R i  for multiscrew extruders with co-rotating and intermeshing screw shafts, in particular for twin-screw extruders, which has in axial cross section through its longitudinal axis ( 10 ) a profile which has at each of the two axial end faces (front end face  8,  rear end face  8 ′) only a screw flight ( 1, 1 ′) corresponding to a conventional single-start screw element for intermeshing screw shafts. In this case, the width (flight land angle φ) of the screw flight ( 1 ) and conversely, in a corresponding way, the width (flight land angle φ) of the screw flight ( 1 ′) are formed in a special way and a shearing flight ( 7 ) with a constant shearing flight radius R s , which is greater than R i  and less than R a , is provided.

[0001] The invention relates to a screw element with an outer radius R_(a) and a core radius R_(i) for multiscrew extruders with co-rotating and intermeshing screw shafts, in particular for twin-screw extruders, which has in axial cross section through its longitudinal axis a profile which has at each of the two axial end faces only a screw flight corresponding to a conventional single-start screw element for intermeshing screw shafts, the surface of which flight, between a left and a right flight edge, is part of a surface of a cylinder with the outer radius R_(a), each end face having a circular root with the core radius R_(i) of the screw shaft and a left and a right flank, which joins the root to the left and right flight edge, respectively.

[0002] The design principles for creating screw elements for co-rotating and closely meshing multiscrew extruders, which are also referred to as Erdmenger profiles, have been known for many years. A corresponding description can be found for example in the book “Der Doppelschneckenextruder, Grundlagen und Anwendungsgebiete” [The twin-screw extruder, principles and areas of application], published by VDI Verlag GmbH, Dusseldorf, 1995 (pages 10-30). In the illustration 1.4 (page 14) of this publication there is shown, for example, an axial cross section of the profile of a single-start screw element of the type mentioned at the beginning.

[0003] For the dispersive and distributive mixing of additives, for example, or other components into plastic compositions, usually kneading blocks which comprise a plurality of kneading disks with an Erdmenger profile, arranged axially one behind the other and offset angularly with respect to one another, are used. The kneading disks are respectively arranged in pairs, lying opposite one another on the two screw shafts of the respective twin-screw extruder, and closely intermesh. The mixing process in conventional kneading blocks is to be regarded as a random process, i.e. the mixing work performed in individual volume elements varies in intensity. Therefore, to achieve a high degree of homogeneity of the mixture, considerable mechanical energy has to be expended to ensure that, as far as possible, every volume unit also undergoes shearing. On the basis of an individual kneading disk, a relatively small proportion of the material to be handled is in each case sheared extremely intensely, while by far the greatest part of the material evades the shearing gap between the shearing disk and the barrel wall and is consequently sheared only little. For this reason, to ensure a high degree of homogeneity of the mixture, either very long kneading blocks of the known type or else high rotational speeds are required. In any event, considerable mechanical energy is expended and is introduced in the form of heat into the material to be handled. In particular during the processing of rubber mixes, the generation of relatively large amounts of heat is extremely undesirable.

[0004] DE 42 39 220 A1 discloses a twin-screw extruder with two identical, closely meshing and co-rotationally driven screw shafts, which are arranged in the bores of a shared barrel. The screw shafts are provided with kneading disks, which have a three-start shaft cross section, that is to say have three flight lands. The distance of the flight lands from the inner surface of the barrel bore and the width of the flight lands vary. The flight land with the greatest flight land width has in this case the smallest distance from the inner surface of the barrel bore. The screw elements known from this document are of a three-start form over their entire axial length.

[0005] The object of the present invention is to develop a screw element of the generic type to the extent that, with the same homogenizing result, a much smaller amount of energy is introduced into the material to be handled.

[0006] This object is achieved according to the present invention in the case of a screw element of the generic type by the features specified in the defining part of patent claim 1. Advantageous developments of the invention emerge from the dependent claims.

[0007] The screw element according to the invention has in cross section through its longitudinal axis a front and a rear end face, which corresponds in its shape to that of a single-start screw element for intermeshing screw shafts of multiscrew extruders. As a result, this screw element can be combined without any problems whatsoever with corresponding conventional single-start screw elements for co-rotating and intermeshing screw shafts on a shared screw shaft. The profile geometry of the screw element is preferably designed for close meshing of the screw elements. In this case, the play between the screw elements and the inner wall of the extruder barrel and between one another, necessary for technical production-related reasons, is usually in the dimensional range of just a few tenths of a millimeter. However, the success according to the invention can also be achieved in significant part if a greater play (in the range of up to several millimeters, for example 1-5 mm, depending on the barrel diameter) is chosen and the screw elements cannot touch one another, that is to say do not closely mesh in the strict sense.

[0008] To avoid misunderstandings, it should be pointed out that the following statements respectively relate to a pair of screws rotating to the right in the direction of the process.

[0009] Over the axial length between the front end face and the rear end face, the shape of this screw element significantly deviates, however, from the known geometry of single-start screw elements, but without losing the property of intermeshing or closely meshing. As it proceeds from the front end face and the flight edge opposite to the rotational sense of the screw element (in the case of rotation to the right, that is to say starting from the left flight edge) along the longitudinal axis up to a partial length x of the axial length l of the screw element, the width of the screw flight (flight land angle) is reduced down to 0 to form an edge. The distance of this edge from the longitudinal axis is initially reduced with increasing distance from the front end face and then increases again, however, until this edge ends in the flight edge corresponding to the rotational sense of the screw element (in the case of rotation to the right, that is to say in the right flight edge) at the rear end face. Conversely, in a corresponding way, as it proceeds from the rear end face and the flight edge corresponding to the rotational sense (in the case of rotation to the right, that is to say the right flight edge) along the longitudinal axis up to a partial length x of the axial length l of the screw element, the width of the screw flight is reduced down to 0 to form an edge, the distance of which from the longitudinal axis is then initially reduced and subsequently, as the distance of the flight surface from the longitudinal axis increases again, ends in the flight edge opposite to the rotational sense of the screw element (in the case of rotation to the right, that is to say the left flight edge) at the front end face. Consequently, instead of having a single flight with a constant flight width and constant distance of the flight surface from the longitudinal axis, this screw element has two flight elements running symmetrically in relation to each other with respect to the longitudinal axis, which in one portion have in each case a constant flight radius as the flight width (flight land angle) decreases and in a further portion have a flight width of 0 (i.e. formation of an edge) and a distance from the longitudinal axis that varies along the longitudinal axis. In addition, however, the screw element according to the invention is also characterized by a further flight, that is a shearing flight. This shearing flight has a shearing flight radius R_(s), i.e. a distance from the longitudinal axis of the screw element which is greater than the core radius R_(i) and less than the outer radius R_(a). The shearing flight extends from that point on the flank corresponding to the rotational sense of the screw element (in the case of rotation to the right, that is to say the right flank) of the front end face, which has the distance Rs from the longitudinal axis, and proceeds in a helical form corresponding to the rotational sense of the screw element to the flank opposite to the rotational sense of the screw element (in the case of rotation to the right, that is to say the left flank) of the rear end face. The shearing flight comprises in its axial length an axial middle piece of substantially constant flight width (i.e. constant flight land angle) and in each case a transitional piece from the middle piece to the front and rear end face, respectively. In these transitional pieces, the flight width is in each case reduced as it increasingly approaches the end face, preferably continuously down to 0 to form an edge, which at the respective end face ends in the flank.

[0010] The described profile of the shearing flight is in principle designed such that it acts in a backward-conveying sense on the material to be handled. This characteristic can be significantly influenced, however, if the shape of the screw element is superposed with an additional pitch, at least over part of its axial length, in that the shape of the screw element is twisted, that is to say cross sections lying one behind the other are turned with respect to one another. On the basis of the axial length of one portion of the screw element, the magnitude of the twisting can, if required, be chosen differently in individual portions. To intensify the backward-conveying effect of the shearing flight, the additional pitch can be brought about by twisting the cross section with respect to the front end face in the direction of the intended rotational direction of the screw element. A reduction in the backward-conveying effect, or even reversal into an especially advantageous forward-conveying effect, can be achieved by the additional pitch being brought about by twisting the cross section with respect to the front end face in the direction counter to the intended rotational direction of the screw element. This embodiment is particularly preferred within the scope of the present invention.

[0011] The additional pitch is expediently superposed on the screw element over its entire length. It is also possible, however, to superpose different additional pitches on a plurality of portions of the screw element lying axially one behind the other.

[0012] The action of the screw element according to the invention is such that the material conveyed by the respective multiscrew extruder is drawn into a screw channel, that is to say into the respective cavity between the screw element and the extruder barrel surrounding the screw element, which is bounded by a shearing flight in the sense of a barrier and the cross-sectional volume of which in the conveying direction is reduced to 0, so that the material is forced in its entirety over the shearing flight. Consequently, a defined shearing and stretching takes place for each volume element of the material to be handled. No special back-pressure elements are required to ensure adequately thorough mixing. Therefore, an extruder system equipped with the screw element according to the invention can be readily run empty. Added to this is the fact that the profile of this screw element according to the invention is self-cleaning if it is designed as a closely meshing screw element. On account of these properties, material changes and also color changes can be accomplished particularly quickly and with minimal effort in the case of an extruder system equipped with the screw elements according to the invention.

[0013] The present invention is explained in more detail below on the basis of the exemplary embodiments represented in the figures, in which:

[0014]FIGS. 1, 2 show respective views of a screw element according to the invention,

[0015]FIG. 3 shows a side view of the screw element according to FIGS. 1 and 2,

[0016] FIGS. 4-10 show axial sections according to FIG. 3 and

[0017] FIGS. 11-12 show perspective views of a screw element according to the invention with additionally superposed pitch.

[0018] The screw element according to the invention, shown in FIGS. 1 and 2 in a perspective view from the front right and the front left, respectively (in FIG. 1a and FIG. 2a as a wire model and in FIG. 1b and FIG. 2b as a surface model) is intended for a right-turning screw shaft, as indicated by the thick arrow entered on the front end face 8. The profile of the end face 8 in the chosen exemplary embodiment is that of a closely meshing single-start Erdmenger screw element. The longitudinal axis of the screw element, which has an axial length l, is denoted by 10. Between the points 5, 6, which are also referred to as flight edges, extends the flight 1, which has a surface in the form of a cylinder shell and is formed in the end section as an arc of a circle with the radius R_(a) about the center point defined by the longitudinal axis 10. The flight width is defined by the flight land angle φ, which is formed between the two radii R_(a) passing through the left and right flight edges 5, 6, respectively. Diametrically opposite the flight 1 lies the root 2, which likewise has a shape in the form of a cylinder shell and is therefore circular in end section. The radius of the root is denoted by R_(i) and corresponds to the core diameter of the associated screw shaft (core radius R_(i)). In the circumferential direction, the root 2 of the end face 8, in a way similar to the flight 1, extends over an angle φ. Between the flight 1 and the root 2 lie two flanks 3, 4, which in the end face 8 respectively correspond to an arc of a circle with the radius R_(a)+R_(i). The circle center point for the flank 4 lies on the opposite left flight edge 5, while the center point of the left flank 3 lies on the opposite right flight edge 6. In principle, it is possible to choose the flight land angle φ for the flight 1 to be different from the flight land angle for the root 2. In this case, however, the mating element meshing with the respective screw element would have to have a correspondingly complementary, different shape. In particular for technical production-related reasons, it is recommendable to choose the two flight land angles to be the same, as in the exemplary embodiment represented according to FIG. 1, in order to allow in each case 2 identical screw elements to intermesh.

[0019] The rear end face 8′, lying opposite the front end face 8, has an entirely identical profile shape. To differentiate from the points or profile lines of the front end face 8, the corresponding points and profile lines of the rear end face 8′ are identified by the same numbering with an additional prime, as revealed by FIGS. 1 and 2. The latter shows the screw element from FIG. 1 in a perspective view from the front left. Between the two end faces 8, 8′, the screw element has the following shape: in the axial direction from the front end face 8 to the rear end face 8′, the width of the flight 1 decreases down to the value 0 as it proceeds from the left flight edge 5 up to an axial partial length x. At the point of the partial length x, both flight edges 5, 6 consequently coincide to form a point and then continue in a common edge 11, which ends in the right flight edge 6′ of the rear end face 8′. The distance of the edge 11 from the longitudinal axis 10 in this case initially decreases over a further part of the axial length and then increases again up to the original value R_(a) at the point 6′. Conversely, in a corresponding way, as it proceeds from the right rear flight edge 6′ in the direction of the front end face 8, the flight width 1′ decreases to the value 0 by the time it reaches an axial partial length x. There, the two flight edges 6′ and 5′ again coincide at a point and continue in an edge 11′ until the left flight edge 5 in the front end face 8 is reached. The edge 11′ has a profile corresponding to the edge 11, that is to say, as it increasingly approaches the end face 8, it initially reduces its distance from the longitudinal axis 10, starting from the original value R_(a), over a certain part of the axial length and, after that, increases again up to the original value R_(a). In addition to the two flight elements similar to each other in the form of the flight 1 and the edge 11 or the flight 1′ and the edge 11′, the screw element according to the invention also has a third flight element in the form of a shearing flight 7, which extends at a constant distance (shearing flight radius R_(s)) from the longitudinal axis 10 as it proceeds from the right flank 4 at the front end face 8 in the direction of rotation intended for the screw element according to the invention (that is to say right-rotating here) up to a corresponding point 9′ on the left flank 3′ at the rear end face 8′. The flight width (measured as the shearing flight land angle from the longitudinal axis 10, not represented in FIGS. 1 and 2) is constant in a middle portion of the axial length l. However, the latter is not absolutely necessary. Between the front end face 8 and the rear end face 8′, the middle piece of the shearing flight 7 respectively continues in a transitional piece up to the two end faces 8, 8′. In this transitional piece, the distance (shearing flight radius R_(s)) from the longitudinal axis 10 remains constant in each case. As it proceeds from the respective end face 8, 8′, the shearing flight 7 initially has the width 0 over a first axial part, that is to say is an edge, and widens in a second axial part from 0 up to the shearing flight width of the middle piece of the shearing flight 7.

[0020]FIG. 3 shows the screw element according to the invention in a side view. Over the axial length l, this screw element is divided into parts, the axial lengths of which are identified by the letters a-g. In the chosen exemplary embodiment, the axial lengths of the parts a and g, b and f, c and e are the same as one another in pairs. A total of 7 sections, which are denoted by the letters A-A to G-G, have been taken through the individual parts, in each case transversely with respect to the longitudinal axis 10. These 7 sections are specifically represented in FIGS. 4 to 10. Comparable salient points of the cross sections are respectively identified by P and a consistent numerical index. To differentiate the individual sections, the numerical index is supplemented by an additional lower-case letter (for example a) corresponding to the respective section (for example A-A). By comparison of the individual sections, the profiles of the flight elements, which are likewise specified in a way corresponding to the identification from FIGS. 1-3, can be specifically followed. Table 1 provides the particulars of parameters for the individual arcs of circles in relation to each of the 7 profile sections (corner points, radius, center point), from which the profile sections A-A to G-G are respectively made up, so that it is possible to dispense with a detailed verbal description.

[0021] Acting representatively for the other sectional diagrams (FIGS. 5 to 10), in FIG. 4 the radii of four circles important for the design have been entered, that is the outer radius R_(a), the shearing flight radius R_(s), the core radius R_(i) and a radius R_(i)+R_(a)−R_(s). Furthermore, the flight land angle φ of the shearing flight 1 is indicated. The angle α denotes the angle by which the right flight edge 6′ is turned about the longitudinal axis 10 (=center point of the respective profile section) with respect to the vertical. However, this angle α has no influence on the design of the profile cross section. β denotes the angle of torsion of the shearing flight 7, which is that angle by which, seen in cross section, the right flight edge of the shearing flight 7, which respectively bears the point designation P₃ (that is to say P_(3a)-P_(3g)), is turned with respect to the right flight edge 6 or 6′ about the longitudinal axis 10. In table 2, the value which the angle β has at the start (start limiting angle) and at the end (end limiting angle) of the respective profile portion is entered for each of the profile portions a-g defined according to FIG. 3. Within the respective profile portion, the angle β changes continuously between these two limiting angles. In addition, it is also indicated in table 2 for each profile portion which value the shearing flight land angle δ respectively has in these profile portions. In the profile portions a and g, the angle δ is in each case constantly equal to 0°, i.e. the shearing flight width is 0 (edge). In the profile portions c, d and e, the shearing flight land angle is in each case at the value δ_(set), i.e. there is a constant shearing flight width. In the two portions b and f, the shearing flight width or the shearing flight land angle δ respectively increases continuously from 0° to the desired value δ_(set) and decreases from this value δ_(set) down to 0.

[0022] FIGS. 4 to 6 show that the width of the flight 1 lying between the points P₇ and P₁ significantly decreases from the section A-A to the section C-C. In FIG. 7, the flight 1 is no longer present and all that remains to be seen is the edge 11 originating from it, on which the point P_(i) (P_(1d)) continues to progress (FIGS. 8-10) in the form of the points P_(1e) to P_(1g), until finally, at the rear end face 8′, it coincides with the rear right flight edge 6′ (FIG. 3). The same correspondingly applies to the flight 1′, which is bounded at the rear end face 8′ by the two flight edges 5′ and 6′ if the FIGS. 4 to 10 are considered in reverse sequence and the progression of the points P₁₀ (P_(10g), P_(10f)) and P₆ (P_(6g)- P_(6a)) is followed.

[0023] With regard to the shearing flight 7, the following can be stated: in FIG. 4, the shearing flight can only be seen in the unsectioned rear part of the flight element. In section A-A, the width of the shearing flight 7 is zero, that is to say it is represented only as an edge at the point P_(3a). In the next figure, FIG. 5, the shearing flight 7 has already reached approximately half its setpoint value, which is indicated by the shearing flight land δ and is also revealed by the side view of the profile portion b in FIG. 3. The section C-C in FIG. 3 shows the shearing flight 7 with its full setpoint width, which extends between the points P_(2c) and P_(3c). This setpoint width of the shearing flight 7 also lies in the next two sections D-D (FIG. 7) and E-E (FIG. 8). In FIG. 9 (section F-F), the two points P₂ and P₃ move closer together again, i.e. the width of the shearing flight 7 in the form of the shearing flight land angle δ decreases again. To this extent, FIG. 9 corresponds to the representation in FIG. 5. In FIG. 10, the shearing flight 7 has again been reduced to an edge, which is represented by the point P_(2g). To this extent, FIG. 10 corresponds to the representation of FIG. 4. Insofar as the individual profile points P₁ to P₁₂ from FIGS. 4 to 10 can be seen in the side view of FIG. 3, they have been entered there.

[0024] In FIGS. 11 and 12, a modification of the screw element according to FIGS. 1-3 is represented from the front left and front right, respectively (in FIG. 11a as a wire model and in FIG. 12b as a surface model). This differs only in that an additional pitch has been superposed on the screw element. In the present example, this additional pitch corresponds to a twisting by turning the profile of the rear end face 8′ with respect to the front end face 8 through a turning angle of 360° counter to the intended direction of rotation of the screw profile (that is to say turning to the left). In the present case, the twisting of the profile cross section was performed uniformly over the entire axial length of the screw profile. As a result, the right flight edge no longer runs parallel to the longitudinal axis 10, as in FIG. 3, but turns with a left twist about the longitudinal axis 10. The left flight edge 5 no longer turns about the longitudinal axis 10 with a right twist, as in FIG. 2, but likewise with a left twist. The same correspondingly applies to the edge 11, in which the left and right flight edges 5, 6 continue. Furthermore, FIG. 11 shows the profile of the shearing flight 7, which no longer turns through more than 180° in a right-turning sense about the longitudinal axis 10, but now in a left-turning sense over an angle of less than 180° from the flank 4 from the proximity of the right flight edge 6 of the front end face to the left flank 3′ into the proximity of the left flight edge 5′ of the rear end face 8′.

[0025] In the present exemplary embodiment, a linear change of the angle β is respectively taken as a basis, that is to say a change which is proportional to the respective axial distance of a profile section from the front end face. It goes without saying that it is also possible to establish a different kind of changing increase of the angle β as a function of the axial length. The same correspondingly also applies to the increase of the angle δ from 0° to the desired setpoint value. With respect to the latter, it should be noted that this setpoint value, that is to say the shearing flight width in the axial middle region of the screw element, does not necessarily have to be strictly constant. A constant shearing flight width means a constant shearing magnitude over the axial length of the shearing flight.

[0026] List of Designations

[0027]1, 1′ screw flight

[0028]2, 2′ root

[0029]3, 3′ left flank

[0030]4, 4′ right flank

[0031]5, 5′ left flight edge

[0032]6, 6′ right flight edge

[0033]7 shearing flight

[0034]8, 8′ front and rear end face, respectively

[0035]9, 9′ point

[0036]10 longitudinal axis

[0037]11, 11′ edge

[0038] x axial partial length

[0039] l axial length

[0040] α turning angle of the profile

[0041] β angle of torsion of the shearing flight

[0042] δ shearing flight land angle

[0043] φ land angle

[0044] R_(a) outer radius

[0045] R_(i) core radius

[0046] R_(s) shearing flight radius

[0047] P_(1a)-P_(12g) points in the profile sections A-A to G-G

[0048] a-g profile portion in the axial direction

[0049] TABLE 1 Profile sections Parameter specification to the circular arcs of the profile sections IV-IV Endpoints P_(1a), P_(3a) P_(3a), P_(4a) P_(4a), P_(5a) P_(5a), P_(6a) P_(6a), P_(7a) P_(7a), P_(1a) Radius R_(a) + R_(i) R_(a) + R_(i) R_(i) R_(a) + R_(i) R_(a) + R_(i) R_(a) Midpoint P_(6a) P_(7a) 10 P_(1a) P_(3a) 10 V-V Endpoints P_(1b), P_(2b) P_(2b), P_(3b) P_(3b), P_(4b) P_(4b), P_(5b) P_(5b), P_(6b) P_(6b), P_(8b) P_(8b), P_(7b) P_(7b), P_(1b) Radius R_(a) + R_(i) R_(S) R_(a) + R_(i) R_(i) R_(a) + R_(i) R_(i) + R_(a) − R_(S) R_(a) + R_(i) R_(a) Midpoint P_(6b) 10 P_(7b) 10 P_(1b) 10 P_(3b) 10 VI-VI Endpoints P_(1c), P_(2c) P_(2c), P_(3c) P_(3c), P_(4c) P_(4c), P_(5c) P_(5c), P_(6c) P_(6c), P_(9c) P_(9c), P_(8c) P_(8c), P_(7c) P_(7c), P_(1c) Radius R_(a) + R_(i) R_(S) R_(a) + R_(i) R_(i) R_(a) + R_(i) R_(a) + R_(i) R_(i) + R_(a) − R_(S) R_(a) + R_(i) R_(a) Midpoint P_(6c) 10 P_(7c) 10 P_(1c) P_(2c) 10 P_(3c) 10 VII-VII Endpoints P_(1d), P_(2d) P_(2d), P_(3d) P_(3d), P_(6d) P_(6d), P_(9d) P_(9d), P_(8d) P_(8d), P_(1d) Radius R_(a) + R_(i) R_(S) R_(a) + R_(i) R_(a) + R_(i) R_(i) + R_(a) − R_(S) R_(a) + R_(i) Midpoint P_(6d) 10 P_(1d) P_(2d) 10 P_(3d) VIII-VIII Endpoints P_(1e), P_(11e) P_(11e), P_(12e) P_(12e), P_(2e) P_(2e), P_(3e) P_(3e), P_(6e) P_(6e), P_(10e) P_(10e), P_(9e) P_(9e), P_(8e) P_(8e), P_(1e) Radius R_(a) + R_(i) R_(i) R_(a) + R_(i) R_(S) R_(a) + R_(i) R_(a) R_(a) + R_(i) R_(i) + R_(a) − R_(S) R_(a) + R_(i) Midpoint P_(6e) 10 P_(10e) 10 P_(1e) 10 P_(2e) 10 P_(3e) IX-IX Endpoints P_(1f), P_(11f) P_(11f), P_(12f) P_(12f), P_(2f) P_(2f), P_(3f) P_(3f), P_(6f) P_(6f), P_(10f) P_(10f), P_(9f) P_(9f), P_(1f) Radius R_(a) + R_(i) R_(i) R_(a) + R_(i) R_(S) R_(a) + R_(i) R_(a) R_(a) + R_(i) R_(i) + R_(a) − R_(S) Midpoint P_(6f) 10 P_(10f) 10 P_(1f) 10 P₂f 10 X-X Endpoints P_(1g), P_(11g) P_(11g), P_(12f) P_(12g), P_(2g) P_(2g), P_(6g) P_(6g), P_(10g) P_(10g), P_(1g) Radius R_(a) + R_(i) R_(i) R_(a) + R_(i) R_(a) + R_(i) R_(a) R_(a) + R_(i) Midpoint P_(6g) 10 P_(10g) P_(1g) 10 P_(2g)

[0050] Profile section Start limiting angle End limiting angle a δ = 0° δ = 0° Section IV-IV $\beta = {\arccos \quad {\left( \frac{{Ra}^{2} + {Rs}^{2} - \left( {{Ri} + {Ra}} \right)^{2}}{2{RaRs}} \right) \cdot \arccos}\quad \left( {1 - \frac{\left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}}} \right)}$

$\beta = {180{{^\circ} \cdot \arccos}\quad \left( \frac{\left( {{Ri} + {Ra}} \right)^{2} - {Ra}^{2} - \left( {{Ri} + {Ra} - {Rs}} \right)^{2}}{{- 2}{{Ra}\left( {{Ri} + {Ra} - {Rs}} \right)}} \right)}$

b δ = 0° δ = δ_(Soll) Section V-V $\beta = {180{{^\circ} \cdot \arccos}\quad \left( \frac{\left( {{Ri} + {Ra}} \right)^{2} - {Ra}^{2} - \left( {{Ri} + {Ra} - {Rs}} \right)^{2}}{{- 2}{{Ra}\left( {{Ri} + {Ra} - {Rs}} \right)}} \right)}$

$\beta = {{180{{^\circ} \cdot \arccos}\quad \left( \frac{\left( {{Ri} + {Ra}} \right)^{2} - {Ra}^{2} - \left( {{Ri} + {Ra} - {Rs}} \right)^{2}}{{- 2}{{Ra}\left( {{Ri} + {Ra} - {Rs}} \right)}} \right)} + \delta_{Soll}}$

c δ = δ_(Soll) δ = δ_(Soll) Section VI-VI $\beta = {{180{{^\circ} \cdot \arccos}\quad \left( \frac{\left( {{Ri} + {Ra}} \right)^{2} - {Ra}^{2} - \left( {{Ri} + {Ra} - {Rs}} \right)^{2}}{{- 2}{{Ra}\left( {{Ri} + {Ra} - {Rs}} \right)}} \right)} + \delta_{Soll}}$

β = arccos ((Ra² + Rs² − (Ri + Ra)²)/(2RaRs)) d δ = δ_(Soll) δ = δ_(Soll) Section VII-VII β = arccos ((Ra² + Rs² − (Ri + Ra)²)/(2RaRs)) $\begin{matrix} {\beta = {{360{{^\circ} \cdot \arccos}\quad \left( \frac{{2{Ra}^{2}} - \left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}} \right)} -}} \\ {{{\arccos \quad \left( \frac{{Ra}^{2} + {Rs}^{2} - \left( {{Ri} + {Ra}} \right)^{2}}{2{RaRs}} \right)} + \delta_{soll}}} \end{matrix}\quad$

e δ = δ_(Soll) δ = δ_(Soll) Section VIII-VIII $\begin{matrix} {\beta = {{360{{^\circ} \cdot \arccos}\quad \left( \frac{{2{Ra}^{2}} - \left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}} \right)} -}} \\ {{{\arccos \quad \left( \frac{{Ra}^{2} + {Rs}^{2} - \left( {{Ri} + {Ra}} \right)^{2}}{2{RaRs}} \right)} + \delta_{soll}}} \end{matrix}\quad$

$\begin{matrix} {\beta = {{180{{^\circ} \cdot \arccos}\quad \left( \frac{{Ra}^{2} - \left( {{Ri} + {Ra} - {Rs}} \right)^{2} - \left( {{Ri} + {Ra}} \right)^{2}}{2{{Ra}\left( {{Ri} + {Ra} - {Rs}} \right)}} \right)} -}} \\ {{\arccos \quad \left( \frac{{2{Ra}^{2}} - \left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}} \right)}} \end{matrix}\quad$

f δ = δ_(Soll) δ = 0° Section IX-IX $\begin{matrix} {\beta = {{180{{^\circ} \cdot \arccos}\quad \left( \frac{{Ra}^{2} - \left( {{Ri} + {Ra} - {Rs}} \right)^{2} - \left( {{Ri} + {Ra}} \right)^{2}}{2{{Ra}\left( {{Ri} + {Ra} - {Rs}} \right)}} \right)} -}} \\ {{\arccos \quad \left( \frac{{2{Ra}^{2}} - \left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}} \right)}} \end{matrix}\quad$

$\begin{matrix} {\beta = {{180{{^\circ} \cdot \arccos}\quad \left( \frac{{Ra}^{2} - \left( {{Ri} + {Ra} - {Rs}} \right)^{2} - \left( {{Ri} + {Ra}} \right)^{2}}{2{{Ra}\left( {{Ri} + {Ra} - {Rs}} \right)}} \right)} -}} \\ {{\arccos \quad \left( \frac{{2{Ra}^{2}} - \left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}} \right)}} \end{matrix}\quad$

g δ 0° δ = 0° Section X-X $\begin{matrix} {\beta = {{180{{^\circ} \cdot \arccos}\quad \left( \frac{{Ra}^{2} - \left( {{Ri} + {Ra} - {Rs}} \right)^{2} - \left( {{Ri} + {Ra}} \right)^{2}}{2{{Ra}\left( {{Ri} + {Ra} - {Rs}} \right)}} \right)} -}} \\ {{\arccos \quad \left( \frac{{2{Ra}^{2}} - \left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}} \right)}} \end{matrix}\quad$

$\begin{matrix} {{\beta = {360{{^\circ} \cdot \arccos}\quad {\left( \frac{{2{Ra}^{2}} - \left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}} \right) \cdot}}}\quad} \\ {{{\arccos \left( \frac{{Ra}^{2} + {Rs}^{2} - \left( {{Ri} + {Ra}} \right)^{2}}{2{RaRs}} \right)} +}} \\ {{\arccos \quad \left( {1 - \frac{\left( {{Ri} + {Ra}} \right)^{2}}{2{Ra}^{2}}} \right)}} \end{matrix}\quad$ 

1. A screw element with an outer radius R_(a) and a core radius R_(i) for multiscrew extruders with co-rotating and intermeshing screw shafts, in particular for twin-screw extruders, which has in axial cross section through its longitudinal axis (10) a profile which has at each of the two axial end faces (front end face 8, rear end face 8′, only a screw flight (1, 1′) corresponding to a conventional single-start screw element for intermeshing screw shafts, the surface of which flight, between a left (5 5′) and a right flight edge (6, 6′), is part of a surface of a cylinder with the outer radius R_(a), each end face (8, 8′) having a circular root (2, 2′) with the core radius R_(i) of the screw shaft and a left (3, 3′) and a right flank (4, 4′), which joins the root (2, 2′) to the left (5 5′) and right flight edge (6, 6′), respectively, of the screw flight (1, 1′), wherein, as it proceeds from the front end face (8) and the flight edge opposite to the rotational sense of the screw element (in the case of rotation to the right, the left flight edge 5) along the longitudinal axis (10) up to a partial length x of the axial length l of the screw element, the width (flight land angle φ) of the screw flight (1) is reduced down to 0 to form an edge, the distance of which from the longitudinal axis (10) is then initially reduced and subsequently, as the distance from the longitudinal axis (10) increases again, ends in the flight edge corresponding to the rotational sense of the screw element (in the case of rotation to the right, the right flight edge 6′) at the rear end face (8′), conversely, in a corresponding way, as it proceeds from the rear end face (8′) and the flight edge (6′) corresponding to the rotational sense along the longitudinal axis up to a partial length x of the axial length l of the screw element, the width (flight land angle φ) of the screw flight (1′) is reduced down to 0 to form an edge (11′), the distance of which from the longitudinal axis (10) is then initially reduced and subsequently, as the distance from the longitudinal axis (10) increases again, ends in the flight edge (5) opposite to the rotational sense of the screw element on the front end face (8), and a shearing flight (7) with a constant shearing flight radius R_(s), which is greater than R_(i) and less than R_(a), proceeds (point 9) from the flank (4) corresponding to the rotational sense of the screw element of the front end face (8) in a helical form corresponding to the rotational sense of the screw element to the flank (3′) opposite to the rotational sense of the screw element of the rear end face (8′) (point 9′), the shearing flight (7) being made up in its axial length of an axial middle piece of substantially constant flight width (flight angle) and, adjoining the latter to the two points (9, 9′) on the flanks (4, 3′), of in each case a transitional piece, the flight width of which is initially reduced to 0 toward the respective end face (8, 8′) and then ends as an edge at the respective point (9, 9′) of the flank (4, 3′) at the end face (8, 8′).
 2. The screw element as claimed in claim 1, wherein the profile is designed for close meshing of the screw element.
 3. The screw element as claimed in claim 2, wherein the shape of the screw element is superposed with an additional pitch (cross-sectional twisting), at least over part of its axial length l.
 4. The screw element as claimed in claim 3, wherein, to intensify a backward-conveying effect of the screw element, the additional pitch is produced by twisting the cross section with respect to the front end face in the direction of the intended rotational direction of the screw element.
 5. The screw element as claimed in claim 3, wherein, to reduce a backward-conveying effect or to produce a forward-conveying effect, the additional pitch is produced by twisting the cross section with respect to the front end face in the direction counter to the intended rotational direction of the screw element.
 6. The screw element as claimed in one of claims 4-5, wherein the additional pitch is superposed on the screw element over its entire axial length l.
 7. The screw element as claimed in one of claims 1-5, wherein different additional pitches are superposed on a plurality of axial portions of the screw element. 